Voltage-sensitive oscillator frequency for rotor position detection scheme

ABSTRACT

A system and method is provided for improved monitoring and controlling of mechanically commutated DC motors. The system and method include DC motors, pulse-count driver circuitry for driving the motors, motor position sensing circuitry, and motor control circuitry. The system and method provide for improved motor current waveform sensing that is able to effectively reject false brake pulses, avoid erroneous processing due to fluctuating battery voltage levels, and reduce the sensitivity to variations in motor current signals due to dynamic motor load, manufacturing variation, system aging, temperature, brush bounce, EMI, and other factors. The system and method also include an improved ability to multiplex additional external motor drivers to the motor control circuitry, select between sequential and simultaneous drive modes using an SPI bit, and monitor the system controller for an error condition and simultaneously driver motors in response to the error condition.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit under 35 U.S.C. §119(e) of U.S.Provisional Application No. 60/723,391, filed on Oct. 4, 2005, theentire disclosure of which is hereby incorporated herein by reference.

TECHNICAL FIELD

The present invention generally relates to the control of electricmotors, and more particularly, to effective and efficient monitoring andcontrol of brush-type DC motors.

BACKGROUND OF THE INVENTION

As technology has progressed, the use of electric motors to performnumerous tasks previously accomplished manually has increaseddramatically. For example, a simple manual task like rolling down avehicle window is performed by the simple push of a button, with a motorperforming the actual work of rolling down the window. The manual actionof opening or closing car vents to redirect hot or cold air to variouslocations is performed simply by changing a temperature setting on acontrol panel. Examples of the use of motors both inside and outside theautomobile field to perform tasks like these abound.

Brush-type DC motors, such as mechanically commutated motors, have beenfound to be especially useful for controlling, for example, the flow ofair in vehicle heating, ventilating and air conditioning (HVAC) systems.With the proliferation of such motors in various applications comes theincreased need to accurately, effectively, and efficiently control themotors. Some applications, including many vehicle HVAC systems, requirethat both the direction and amount of rotation of multiple brush-type DCmotors be accurately measured and controlled in order for the systems tofunction effectively. In addition to requiring the ability to controlthese aspects of motors, most manufacturers are driven by the market tosearch for ways to minimize the costs of the motors and their associatedcontrol systems.

Several methods for monitoring the performance of brush-type DC motorsand effectively controlling them have been described in U.S. patents.One method, based on detection of the rapid change in current (i.e.,falling edge, interruptions, discontinuities, or fluctuations) due tothe commutation process, is commonly referred to as commutation spike orripple detection. In a conventional pulse count system, commutationspikes are detected in the current waveform characteristics of abrush-type DC motor and used as feedback signals to determine the rotorposition. This concept is based on the general principle of detectingthe rapid change in current due to the periodic commutation process of arotating motor. The basic schemes typically consist of sensing the motorcurrent and then conditioning the sensed signal by various techniquessuch as filtering and amplification or by differentiation. The processedsignal is then amplitude qualified by comparing it to a detectionthreshold, which triggers a pulse generator. The digital pulse can befed back to a microcontroller for further processing of the rotorposition information. This additional processing can include, forexample, using the current position of the motor to determine the natureof control signals that should be sent to this or other motors in thesystem.

Conventional methods of commutation spike detection generally rely onmotor current waveform characteristics, which can be highly variable dueto a number of factors. These factors include motor manufacturingtolerances and aging effects, dynamic motor loading, temperatureeffects, and supply voltage fluctuation. Signal degradation due to brushbounce and other noise caused by motor aging can be a major cause ofaccuracy and reliability concerns. Another drawback is thesusceptibility of detection circuitry to electromagnetic interference(EMI), cross-talk and other sources of noise. Detection thresholds mustbe set to the minimum motor current amplitude, resulting in poor signalto noise ratios and susceptibility to noise in very light loadconditions. In addition, applications using asymmetric (unbalanced)magnetized motors are often sensitive to very light and assisted loads,which can result in very unreliable commutation characteristicsrequiring prediction techniques to achieve desired accuracy.

Another drawback with using a conventional commutation spike detectionscheme for determining the shaft position in DC motors relates to thesystem voltage level. For example, in an automobile application, athigher battery levels, motor speed is proportionally faster than it isat lower battery voltage levels. A conventional commutation spikedetection scheme generates an output pulse (e.g. one-shot) for eachqualified commutation spike. A blanking or “dead” time following theone-shot output is often used to provide additional noise immunity,which prevents inadvertent triggering on high frequency noise that oftenprecedes a commutation event, resulting in the generation of falsepulses. To avoid generating false pulses, the duration of one-shot andblanking-time signals needs to linearly track the motor speed, which isdependant on the battery voltage level.

An additional drawback with a commutation spike detection scheme occurswhen the motor is braked. In a typical brush-type DC motor application,motor braking is accomplished by short circuiting the windings of themotor. For an H-bridge configuration, this is normally accomplished byturning on both low-side drivers or both high-side drivers and turningoff the opposite half of the H-bridge. At the moment the motor windingsare shorted, the energy stored in the motor windings will generate asignificant kickback voltage, which contains the same frequency contentas the commutation spike. If the brake command is processed after theblank time of a valid commutation event, a false trigger will often begenerated. This is known as a “false brake pulse”, and results in anerror in pulse counting. Because the control logic that sends the“brake” signal is asynchronous relative to the spike detectioncircuitry, the inductive kickback due to the shorting of the motorwindings in response to a “brake” signal can be detected as a falseevent, resulting in an error in pulse counting. Due to motor speed andthe processing complexity required to synchronize a brake command withthe pulse detection circuitry, implementation of a system to rejectfalse brake pulses can be difficult. What is needed is a simple andeffective means to synchronize the motor control and pulse detectionlogic in a circuit that rejects false brake pulses.

In addition to facing the above-described limitations in detecting andprocessing signals, developers and manufacturers of systems requiringmultiple brush-type DC motors also face problems of controlling themotors with optimum efficiency and cost. While pulse count technologyserves as a low-cost actuator position feedback alternative topotentiometer feedback or optical encoder systems, there is still a needto minimize the cost of this technology. There have been attempts tointegrate the circuit elements for control logic, signal processing,feedback, and power stages of the motor control system into a singlepackage. For the power stage, an H-bridge topology is typically employedfor each motor to be driven. The number of driver channels is typicallylimited to between 1 and 4 due to the size and cost of the powertransistors required for the H-bridge circuits, the number of motors persystem, and the number of systems. It is generally not cost effective tohave more than one spare channel driver in a given motor drive circuitor integrated circuit (IC) in the conventional system.

When system requirements dictate the need for more driver channels thanare available in a single IC package, the designer is often faced with atradeoff between using additional ICs and wasting the spare channels(since not all channels on the new IC are needed), or alternativelyusing more costly discrete driver technology. In pulse countapplications that use a sequential drive scheme (i.e., individualhigh-side drivers with common low-side transistor pairs that allow forone motor to operate at a time), this can be accomplished by adding anexternal high-side driver pair and sharing the common return inside theIC, for example. While this solution is simple, it is limited inperformance because only one motor can be controlled at a time, and alsobecause adding additional drivers increases the total system throughputtime. This situation often typically makes it impossible to takeadvantage of the low cost of pulse count systems in high-end systems,where throughput is critical to total performance.

Finally, in applications requiring bi-directional control of multiplemotor actuators, such as those found in automotive climate controlsystems, for example, design teams are often faced with making anothertradeoff between system cost and system performance. In DC motorapplications employing bi-directional motor control, an H-bridge powerstage configuration is often employed. An H-bridge configurationtypically consists of four power switches, such as field-effecttransistors (FETs) or bipolar junction transistors (BJTs), arranged in aconfiguration resembling the letter “H.” The upper legs, commonlyreferred to as the high-side of the bridge, typically consist of two topswitches connected between a common supply voltage and both motorterminals. The lower legs, commonly referred to as the common orlow-side of the bridge, typically consist of two bottom switchesconnected between both motor terminals and ground. The motor is usuallylocated in the middle, and its state of operation is controlled by thestate of the power switches.

With the H-bridge motor control configuration, to drive the motor in theforward direction, the high-side driver connected to the positiveterminal of the motor, and the low-side driver connected to the negativeterminal of the motor, are turned on to allow electric current to flowthrough the motor coils. To drive the motor in the reverse direction,the polarity of the motor is reversed by turning on the opposite high-and low-side drivers, and reversing the direction of current flow.Braking is achieved by shorting the motor coils by turning on bothlow-side drivers and turning off both high-side drivers.

To reduce cost in systems controlling multiple motors, H-bridges areoften integrated into a single package, along with associated controlcircuitry. To further reduce system cost, a sequential drive scheme canbe chosen to allow a further reduction in drivers and wiring. Thisapproach consists of having multiple motors share a common low-sidedriver of the H-bridge while retaining individual high-side drivers foreach motor. This approach results in a benefit of reducing system costbecause of the reduction in the amount of wire required due to thecommon wiring connection to the low-side. However, there is asignificant impact on the response time which can degrade systemperformance.

When system performance is critical, a simultaneous drive scheme may beadopted. However, this does not allow for selectable configuration ofsimultaneous or sequential drive operation in a single package.Therefore, the designer is forced either to have two different driversolutions to meet the challenges of various customers, or to limititself to a single solution that is either not cost effective and/or oflimited performance. A single driver configuration is needed that allowsthe capability of selecting either a sequential operation when systemperformance is not critical and low cost is important, or a simultaneousoperation when system performance is critical and the cost can bejustified.

In addition, designers implementing motor driver solutions are oftenrequired to meet various standards. For example, designers implementingsolutions for vehicle HVAC systems must meet certain standards relativeto how the system responds during failure modes. It is thereforedesirable for the system to support fail-safe features necessary to meetvarious standards.

SUMMARY OF THE INVENTION

In accordance with one aspect of the present invention, a method andsystem for eliminating or significantly reducing the sensitivity tonoise and variation in motor current waveform characteristics (e.g.amplitude and shape) caused by, for example, motor aging and dynamicload conditions, is provided. The method and system are not dependent onthe high-frequency characteristics of the motor current waveformproduced by the rapid change in current during commutation. The methodand system use relative maximum and minimum values of motor sinusoidalcurrent levels typically caused by the time-varying back-EMF generateddue to the relationship of the rotor position with the magnetic flux,along with adaptive thresholds, to generate pulses representingincremental angular displacement of the rotor used to determine motorshaft position.

In accordance with another aspect of the present invention, a method andsystem for a motor position detection system and method that is lesssensitive to the system battery voltage is provided. The method andsystem utilize an oscillator, with its current reference set by anexternal resistor tied to the battery voltage, to alter one-shot andblanking time with changes in the battery voltage levels. At least oneof frequency and duration of the pulses issued by the pulse-generatingcircuitry is varied linearly as a function of the system battery level.

In accordance with yet another aspect of the present invention, a methodand system for controlling braking of a motor so as to avoid false brakepulses in a motor position detecting system is provided. The method andsystem involve synchronizing the motor control input signals with thepulse detection circuitry in order to mask false brake pulses. Themethod includes the steps of operating motor control circuitry of thebrush-type DC motor with motor position detecting circuitry, andmonitoring the motor position detecting circuitry in the motor controlcircuitry for presence of a blanking time signal. The method alsoincludes the steps of detecting the presence of a blanking time signaland issuing a braking signal from the motor control circuitry, when themotor control circuitry detects that the motor position detectingcircuitry is issuing a blanking time signal. The duration of the brakingsignal is less than the duration of the blanking time signal issued bythe motor position detecting circuitry.

In accordance with still another aspect of the present invention, amethod and system for multiplexing external motor drivers to a pulsecount driver with a simultaneous drive scheme is provided. The methodand system utilize additional discrete circuitry to extend the drivercapability of a pulse count driver supporting multiple channels and DCmotors, to control additional channels and DC motors, with the abilityto drive a plurality of the channels simultaneously.

In accordance with yet another aspect of the present invention, a methodand system for allowing the selectable configuration of a multipleH-bridge driver so that it can be used in either a sequential orsimultaneous drive configuration is provided. In the simultaneous mode,all H-bridges will respond to their individual control inputs and workindependently of the state of the other H-bridges. In the sequentialmode, all H-bridges will share a common bottom side, allowing forelimination of extra wires required in simultaneous driver mode. In thismode, the operation of individual H-bridges will be dependent on thestate of the others due to the common bottom side. The driverconfiguration will be determined by the state of a single serialperipheral interface (SPI) control input bit.

In according with yet another aspect of the present invention, a methodand system for allowing the motor control circuitry to respond in apredetermined method in response to a system failure is provided.According to this aspect of the present invention, motor controlcircuitry is configured to monitor a bit from an external controlcircuit. That bit indicates when external control circuitry is notoperating properly. When the motor control circuitry determines that theexternal circuitry is not operating properly, it drives the motors thatit controls to predetermined positions.

These and other features, advantages and objects of the presentinvention will be further understood and appreciated by those skilled inthe art by reference to the following specification, claims and appendeddrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described, by way of example, withreference to the accompanying drawings, in which:

FIG. 1 is a block diagram illustrating an electrical motor controlsystem controlling mechanically commutated DC motors, according to afirst embodiment of the present invention;

FIG. 2 is a block diagram further illustrating the motor controlcircuitry for controlling multiple motors;

FIG. 3 is a block/circuit diagram illustrating an analog circuitimplementation for a MAX-MIN detection circuit of the motor controlcircuit, according to one embodiment of the present invention;

FIG. 4 is a flow diagram illustrating an electronic motor controlroutine, according to one embodiment of the present invention;

FIG. 5 is a flow diagram illustrating an electronic motor control brakeroutine, according to one embodiment of the present invention;

FIG. 6 is a timing diagram showing various signals relating to thesteady state operation of an asymmetric motor in a system implementedaccording to one embodiment of the present invention;

FIG. 7 is a timing diagram showing various signals associated with thesteady state operation of a symmetric motor in a system operatingaccording to one embodiment of the present invention;

FIG. 8 is a timing diagram showing various signals associated with amotor during a starting operation in a system implemented according toone embodiment of the present invention;

FIG. 9 is a block diagram illustrating an electronic motor controlsystem, according to a second embodiment of the present invention;

FIG. 10 is a circuit diagram illustrating a variable oscillatorassociated with the motor control system shown in FIG. 9;

FIG. 11 is a circuit diagram further illustrating variable one-shotduration circuitry associated with the motor control system shown inFIG. 9;

FIG. 12 is a block diagram illustrating an electronic motor controlsystem, according to a third embodiment of the present invention;

FIG. 13 is a circuit diagram illustrating a brake filtering circuitemployed in the motor control system shown in FIG. 12;

FIG. 14 is a state diagram of one embodiment of a control routine forthe electronic motor control system shown in FIG. 12;

FIG. 15 is a block diagram illustrating an electronic motor controlsystem, according to a fourth embodiment of the present invention;

FIG. 16 is a state definition matrix illustrating the state of varioussystem components in the motor control system shown in FIG. 15;

FIG. 17 is a circuit diagram illustrating motor multiplex controlcircuitry and interfaces employed in the motor control system shown inFIG. 15;

FIG. 18 is a block diagram illustrating an electronic motor controlsystem, according to a fifth embodiment of the present invention;

FIG. 19 is a block diagram illustrating an alternate configuration ofthe motor control system shown in FIG. 18;

FIG. 20 is a block diagram further illustrating simultaneous control ofthe multiple DC motors in the system shown in FIG. 18;

FIG. 21 is a block diagram illustrating sequential control of themultiple DC motors in the system shown in FIG. 18;

FIG. 22 is a state definition matrix showing the state of variouscircuitry employed in the motor control system of FIG. 18; and

FIG. 23 is a block diagram illustrating an electronic motor controlsystem implementing together features of various embodiments of thepresent invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIG. 1, an electrical motor control system is generallyillustrated controlling brush-type DC motors 30, which, in turn, actuatemotor controlled devices 70. The motor control system generally includesa microcontroller 12 and motor control circuitry 10 in the form of anapplication specific integrated circuit (ASIC). The motor controlcircuitry 10 includes pulse count driver circuitry 20, sensing anddetection circuitry 40, one-shot circuitry 50, and control logic 12. Themotor control system may be used to control electrical DC motors in anynumber of applications, including, for example, actuation of air ductdoors in automobile HVAC systems.

The motor control system is generally shown controlling brush-type DCmotors 30. Brush-type DC motors 30 are typically permanent magnet DCmotors with brushes. Brush-type DC motors are typically mechanicallycommutated. Brush-type DC motors have a rotor (armature) and a stator(permanent magnet or field coils) that cause the motors to rotate whenelectrical signals are applied. The motor control system and controlmethodology may be employed to control any of a number of one or morebrush-type DC motors 30 and monitor the motor position (e.g., motorrotor or shaft position) for use in any of a number of applications.Motors 30 are typically connected to any number of motor control devices70 for a given application.

The microcontroller 12 may include a general purpose controller or aspecifically configured controller for controlling the overall operationof the DC motors 30 for one or more applications. The microcontroller 12monitors the output of the ASIC 10 and generates command signals todrive and brake any number of the motors, based on a motor controlroutine of a given application. Microcontroller 12 may take the form ofa controller employing a microprocessor and memory. The microprocessormay include a conventional microprocessor having the capability forprocessing routines and data. The memory may include read-only memoryROM, random access memory RAM, flash memory, and other commerciallyavailable volatile and non-volatile memory devices. Stored within thememory may be data and routines. Microcontroller 12 may alternately bein the form of alternative digital and/or analog circuitry.

The motor control circuitry 10 receives control command signals frommicrocontroller 12, drives the DC motors 30, and monitors sense currentpassing through the DC motors 30. The motor control circuitry 10 maytake the form of integrated circuitry, such as an ASIC, or other analogand/or digital circuitry. The motor control circuitry 10 may beimplemented in a separate dedicated microcontroller having amicroprocessor and memory, or may be implemented in a shared controller,such as microcontroller 12.

The motor control circuitry 10 is generally shown having logic 14 forprocessing data and executing control routines 100 and 200, pulse countdriver circuitry 20 capable of receiving signals from logic 14 anddriving external motors via H-bridge 24, one-shot circuitry 50 capableof issuing pulses to pulse count driver circuitry 20 and microcontroller12, and sensing and detection circuitry 40 for monitoring motor currentvia H-bridge 24 and issuing signals to one-shot circuitry 50. Theelements comprising motor control circuitry 10, including pulse countdriver circuitry 20, one-shot circuitry 50, H-bridge 24, routines 100and 200, logic 14, registers 16 and SPI circuitry 18, and sensing anddetection circuitry 40 may be implemented using discrete components, asa stand-alone integrated circuit, or as part of a more comprehensiveintegrated circuit providing a variety of functions.

To control the DC motors 30, pulse count driver circuitry 20 employs anH-bridge power stage 24, according to one embodiment. An H-bridgegenerally includes four power switches, such as FETs or BJTs arranged ina configuration resembling the capital letter H (see FIG. 13 for anexample of an H-bridge 24 connected to a motor 30). The upper two legsof the H-bridge, commonly referred to as the high-side of the bridge,include two top switches connected between a common supply voltage andboth motor terminals. The lower two legs, commonly referred to as thecommon or low-side of the bridge, include two bottom switches connectedbetween both motor terminals and ground. The motor(s) is located in themiddle and, therefore, the motor state of operation is controlled by thestate of the power switches implemented in the pulse count drivercircuitry 20 and H-bridge 24.

To drive the motor(s) in the forward direction, the high-side driverconnected to the positive terminal and the low-side driver connected tothe negative terminal of the motor are turned on to allow current toflow through the motor coil. To drive the motor(s) in the reversedirection, the polarity applied to the motor(s) is reversed by turningon the opposite high and low-side drivers and reversing the direction ofcurrent flow. Braking is achieved by shorting the motor coils by turningon both low-side drivers and turning off both high-side drivers or viceversa. The pulse count driver circuitry 20 may take the form of multipleH-bridges integrated into a single package, along with control circuitryto receive motor control signals from external devices and control theH-bridges for a plurality of brush-type DC motors.

The motor control system in FIGS. 1 and 2 is also generally shown havingsensing and detection circuitry 40 for assisting in the determination ofthe rotor position of brush-type DC motors 30. One circuitry blockwithin sensing and detection circuitry 40 detects and conditions motorcurrent levels from motors 30. In addition to detecting and conditioningthe output current from motors 30, sensing and detection circuitry 40also issues triggers to one-shot circuitry 50, based on the conditionsignals from motors 30. One-shot circuitry 50 produces a digital pulseoutput of a specified length, based on triggers received from sensingand detection circuitry 40. One-shot circuitry 50 also issues adead-time signal of a specific duration to improve noise immunity andsimplify the interface of one-shot circuitry 50 to off-chip digitallogic.

The motor control system generally illustrated shows the output fromone-shot circuitry 50 being provided to microcontroller 12 for use indetermining the position (motor rotor or shaft position) of brush-typeDC motors 30. Sensing and detection circuitry 40 may be implemented withdiscrete components, may take the form of a dedicated integratedcircuit, or may be incorporated into a more general purpose integratedcircuit providing additional functions. One-shot circuitry 50 may beimplemented using discrete components, may be implemented in the form ofa dedicated integrated circuit, or may be integrated into a more generalpurpose integrated circuit providing additional functions.Microcontroller 12, pulse count driver circuitry 20, H-bridge 24,one-shot circuitry 50, and sensing and detection circuitry 40 may all becombined together in one dedicated integrated circuit, or into a moregeneral-purpose integrated circuit (e.g., microcontroller) providingadditional functions.

FIG. 2 illustrates a block and circuit diagram showing an ASIC used toimplement the motor control circuitry 10 to perform certain aspects ofthe present invention. ASIC 10 is generally shown having a first motorcontrol circuit 10A, a second motor control circuit 10B, a third motorcontrol circuit 10C, and a fourth motor control circuit 10D. Each ofthese motor control circuits is shown controlling a brush-type DC motor30. The discussion of the components in first motor control circuit 10Awill also apply to second motor control circuit 10B, third motor controlcircuit 10C, and fourth motor control circuit 10D. First motor controlcircuit 10A is shown having a voltage level decoder 22 for decodingsignals received from a microcontroller, gate drive logic 23 forreceiving signals from voltage level decoder 22 and providing controlsignals to H-bridge 24, and an H-bridge 24 for driving motor 30. Firstmotor control circuit 10A is also shown having a sensing circuit 43 forsensing the current provided to motor 30 by H-bridge 24 and forproviding a voltage signal to MAX-MIN detection state machine 42. Thevoltage signal provided by sensing circuitry 43 to MAX-MIN detectionstate machine 42 corresponds to the instantaneous motor current sensedby sensing circuitry 43. The configuration of MAX-MIN detection statemachine 42 is determined by one-shot duration (OSD) bits, positivethreshold (PThr) bits, negative threshold (NThr) bits and brakethreshold (BThr) bits. MAX-MIN detection state machine 42 is also shownreceiving a peripheral clock signal PCLK and a brake signal. MAX-MINdetection state machine 42 is also shown sending an output one-shotpulse OS1 which is applied to the microcontroller.

FIG. 3 illustrates an analog implementation of MAX-MIN detection statemachine 42 illustrated in FIG. 2, according to one embodiment of theinvention. Maximum hold voltage block 91 detects and holds maximumvoltage levels of VIN, while minimum hold voltage block 92 detects andholds minimum voltage levels of VIN. As noted above, VIN shown in FIG. 3corresponds to the current sensed by current sense circuitry 43 fromH-bridge 24, as shown in FIG. 2. The values of maximum hold voltage 91and minimum hold voltage 92 pass through a resistor divider network as anegative threshold at comparator 93 and a positive threshold atcomparator 94. Comparators 93 and 94 compare the negative threshold andpositive threshold with the input voltage. When comparator 93 determinesthat the input voltage has dropped below the negative threshold value orwhen comparator 94 has determined that the input voltage has risen abovethe positive threshold value, a one-shot will be issued by one-shotcircuitry tied to comparators 93 and 94. The one-shot signals tied tocomparators 93 and 94 are then logically ORed in OR gate 95 and outputas a one-shot signal. Once a one-shot signal is issued from the one-shotcircuitry tied to comparator 94, the minimum hold voltage in minimumhold voltage block 92 is reset to the current level of VIN. Once aone-shot pulse issues from the one-shot circuitry tied to comparator 93,the maximum hold voltage of maximum hold voltage circuit block 91 isreset to match the level of VIN. The result is a dynamic redeterminationof maximum and minimum hold voltages leading to variable positive andnegative threshold levels. This results in one-shot circuitry that isless sensitive to spurious current and voltage fluctuation.

It should be noted that the various resistor values in resistor dividernetwork can be changed to vary the one-shot triggering levels. AlthoughFIG. 3 shows an analog implementation of the MAX-MIN detection statemachine, according to one embodiment of the invention, other analog anddigital implementations are possible, including implementations usingsoftware.

In addition, although FIGS. 1-2 show motor control circuitry 10 beingimplemented in an ASIC, it should be appreciated that the variousfunctions performed by motor control circuitry 10 could be implementedusing discrete components, integrated circuits, and/or a microprocessorconnected to memory and having I/O and the capability to executeroutines 100 and/or 200.

The operation of the motor control system generally illustrated in FIG.1 is now discussed according to one embodiment of the present invention.The brush-type DC motors 30 are caused to rotate, based on voltageapplied to the motor terminals by the H-bridge 24 of pulse count drivercircuitry 20.

Sensing and detection circuitry 40 detects and conditions the currentlevels applied to motors 30 by H-bridge 24 by determining relativemaximum and minimum motor current levels in the detected signals frommotors 30, and using those relative minimum and maximum levels toestablish an adaptive threshold. Optionally, a portion of this currentis low-pass filtered prior to reaching sensing and detection circuitry40. Once sensing and detection circuitry 40 determines that the electriccurrent from motors 30 has reached an adaptive threshold, pulses aregenerated by sensing and detection circuitry 40 to one-shot circuitry50.

By monitoring relative maximum and minimum values of the current flowingin the motors 30 controlled by the state of the H-bridge 24 and usingthat information to adapt the detection threshold used to determinerotor position, sensing and detection circuitry 40 is able to issuetriggers to one-shot circuitry 50 that more accurately reflect theactual motor position of each of the DC motors 30. When one-shotcircuitry 50 receives a trigger from sensing and detection circuitry 40,its outputs go low. At this point, additional pulses from sensing anddetection circuitry 40 will have no effect on one-shot circuitry 50.Once enabled, the output of one-shot circuitry 50 will remain low for apredetermined duration. In addition to the one-shot pulse, there is asecond dead-time of the same duration as the one-shot pulse for whichthe outputs of one-shot circuitry 50 will remain high, regardless ofadditional pulses being received from sensing and detection circuitry40. This feature allows greater immunity to noise in sensing anddetection circuitry 40, and simplifies interfacing to off-chip digitallogic.

The width of the one-shot output pulse of one-shot circuitry 50, as wellas its retriggering period, also known as dead-time, is determined bythe frequency of a clock signal provided to one-shot circuitry 50. Thisfrequency is typically set via an oscillator input. In the specific ASICimplementation shown in FIG. 2, the duration of the one-shot is alsodetermined by the value of OSD bits in a register in the MAX-MINdetection state machine 42. Returning to FIG. 1, output voltage levelVOH for one-shot circuitry 50 is typically set by an IOREF pin. Itshould be noted that a pulse from sensing and detection circuitry 40 mayoccur anywhere in a clock period, i.e., motor pulses are asynchronous tothe internal clock of one-shot circuitry 50.

FIGS. 4 and 5 illustrate the operation of the motor control system,according to one embodiment of the present invention. It should be notedthat PThr, NThr, and BThr are predefined values provided during systemdesign or programming. Preferred values for positive threshold PThrrange from, but are not limited to, 10 percent to 60 percent, with 20percent being a preferred value, according to one embodiment of thepresent invention. Preferred values for negative threshold NThr rangefrom, but are not limited to, 40 percent to 90 percent, with a preferredvalue being 60 percent, according to one embodiment of the presentinvention. Preferred values for brake threshold BThr include, but arenot limited to, one divided by 64, one divided by 32, and one divided by16, with a preferred value for BThr being one divided by 128.

FIG. 4 illustrates a motor control routine 100 for controlling theoperation of motor control circuitry shown in FIG. 1 during a clockwiseor counterclockwise rotation of the motor in the run mode. Routine 100begins the run mode by starting the motor(s) in the clockwise orcounterclockwise rotation in block 110. After a clockwise orcounterclockwise command is issued to the motor(s), circuitry withinsensing and detection circuitry 40 detects when the initial maximumcurrent level (IMAX) is reached in decision block 112 and then storesthat value in block 114. Routine 100 then checks for detection of amotor brake or stall condition in decision block 116 and, if detected,exits to the brake routine in block 138. The routine 100 also detectsfor whether the minimum current level (IMIN) is reached in decisionblock 118 and, if reached, stores the IMIN in memory. Otherwise, theroutine returns to block 116. Circuitry within sensing and detectioncircuitry 40 may detect and hold the maximum and minimum current levels.

Once the first minimum is detected in block 118 and stored in block 120,routine 100 then checks for a brake or stall condition in block 122. Ifa brake or stall condition is detected, routine 100 exits to the brakeroutine in block 138. If a brake or stall condition is not detected,temporary maximum sample and hold circuitry that is part of sensing anddetection circuitry 40 tracks the increasing current. At this point, oneof two events occurs. In block 124, if the current level does not exceedPThr times the difference between IMAX and IMIN plus IMIN, routine 100proceeds back to block 122. If, however, in block 124, the currentexceeds PThr times the difference between IMAX and IMIN plus IMIN,routine 100 proceeds to block 126. In block 126, sensing and detectioncircuitry. 40 issues an initial trigger pulse to one-shot circuitry 50causing one-shot circuitry 50 to issue a one-shot pulse. The valuestored from IMIN and the stall timer are also cleared.

After checking in block 128 for a brake or stall condition, routine 100proceeds to block 130 and detects for a new IMAX level. If a new levelhas not been detected, routine 100 proceeds back to block 128. If a newIMAX level has been detected, routine 100 proceeds to block 132 and anew IMAX value is stored. Routine 100 then proceeds to block 134, wherecircuitry determines if the output current has fallen below NThr timesIMAX minus IMIN plus IMIN. If not, routine 100 returns to block 128. If,however, the current is less than NThr times IMAX minus IMIN plus IMIN,routine 100 proceeds to block 136, where a trigger pulse is issued toone-shot circuitry 50, which, in turn, issues a one-shot pulse. In block136, the stored values for IMIN and the stall timer are also cleared.Routine 100 then returns to block 116.

FIG. 5 illustrates a routine 200 performed by motor control circuitrygenerally illustrated in FIG. 1 during a braking condition. Routine 200begins with a start braking command in block 210. Routine 200 thenproceeds to block 212. Block 212 determines whether an IMAX has beenreached. If not, routine 200 returns to the top of block 212 andcontinues to wait until a maximum current has been reached. If a maximumcurrent has been reached, routine 200 proceeds to block 214, where themaximum current value is stored. Routine 200 then proceeds to block 216,where the current level is compared with BThr. If the current level isless than BThr, routine 200 proceeds to exit at block 236. If thecurrent is not less than BThr, routine 200 proceeds to block 218. Block218 determines if a minimum current level has been reached. If a minimumcurrent level has not been reached, routine 200 proceeds to thebeginning of block 216. If a minimum current level has been reached,routine 200 proceeds to block 220, where the value of the minimumcurrent is stored. Routine 200 then proceeds to block 222.

In block 222, the current level is again compared to BThr. If thecurrent level is less than BThr, routine 200 proceeds to block 236 exit.If the current level is not less than BThr, routine 200 proceeds toblock 224. In block 224, current level is compared to 0.05 times IMAXminus IMIN plus IMIN. If the current level is not greater than thisvalue, routine 200 proceeds to block 222. If the current level isgreater than this value, routine 200 proceeds to block 226. In block226, a trigger pulse is issued from sensing and detection circuitry 40to one-shot circuitry 50, which then issues a one-shot pulse. Routine200 then proceeds to block 228, where the current level is againcompared to BThr. If the current level is less than BThr, routine 200proceeds to block 236 exit. If the current level is less than BThr,routine 200 proceeds to block 230, where the current level is comparedto the value of IMAX. If the value of IMAX has not been reached, routine200 proceeds to block 228. If the IMAX level has been reached, routine200 proceeds to block 232 and the new value for IMAX is stored. Routine200 then proceeds to block 234, where the value for IMIN is cleared.Routine 200 then proceeds back to block 216.

FIG. 6 is a timing diagram showing the output of one-shot circuitry 50and the input to sensing and detection circuitry 40 during steady stateoperation of an asymmetric motor. The voltage signal VIN shown in thebottom half is derived from the current provided to an asymmetric motor30 by H-bridge 24. One-shot pulses are issued when the voltage leveleither rises above PThr times the difference between the maximum andminimum voltages, or falls below NThr times the difference between themaximum and minimum voltages. In this case, PThr has been selected to betwenty percent (20%) and NThr has been selected to be sixty percent(60%). As noted above, other values for PThr and NThr can be selected.In one embodiment in which an asymmetric motor is controlled, one-shotpulses are issued both when the voltage level rises above PThr times thedifference between the maximum and minimum voltages and when the voltagelevel falls below NThr times the difference between the maximum andminimum voltages.

FIG. 7 is a timing diagram showing the output of one-shot circuitry 50and the input to sensing and detection circuitry 40 during steady stateoperation of a symmetric motor. The voltage VIN shown in the bottom halfis a voltage derived from the current provided to a symmetric motor 30by H-bridge 24. As in FIG. 6, one-shot pulses are issued when thevoltage level either rises above PThr times the difference between themaximum and minimum relative voltage levels, or falls below NThr timesthe difference between the relative maximum and minimum voltage levels.In one embodiment in which a symmetric motor is controlled, one-shotpulses are issued only when the voltage level rises above PThr times thedifference between the maximum and minimum voltages.

FIG. 8 is a timing diagram showing the output of one-shot circuitry 50and the input to sensing and detection circuitry 40 during a motorstarting operation. VIN shown in the bottom half is a voltage derivedfrom the current provided to motor 30 by H-bridge 24. As in FIGS. 6 and7, one-shot pulses are issued when the voltage VIN either rises abovePThr times the difference between the relative maximum and minimumvalues of a voltage, or falls below NThr times the difference betweenthe relative maximum and minimum voltage levels. As with FIGS. 6 and 7,NThr and PThr can be selected to have different values.

Referring to FIG. 9, an electric motor control system is generallyillustrated, according to a second embodiment of the present invention.In addition to the elements included in the first embodiment generallyillustrated in FIG. 1, the motor control system in the second embodimentfurther includes an oscillator 51 tied to a battery voltage(V_(BATTERY)). The oscillator 51 is coupled to one-shot circuitry 50 tocontrol the frequency of one-shot and blanking pulses. The motor controlsystem in the second embodiment operates in a manner similar to thatdescribed in the first embodiment, with the added benefit that theoscillator 51 tied to the battery voltage (V_(BATTERY)) causes theone-shot and blanking time of one-shot circuitry 50 to vary linearlywith the voltage of the battery. This is because pulses output byone-shot circuitry 50 are coordinated with a PCLK signal derived fromthe oscillator 51. As the battery voltage changes, the oscillator 51frequency changes, causing the PCLK input signal frequency to change,and varying the resulting one-shot frequency and duration.

Referring to FIG. 10, the oscillator 51 and one-shot circuitry 50 areillustrated according to one exemplary embodiment for generatingone-shot and blanking pulses. The variable oscillator 51 receives as aninput an ignition voltage VIGN (e.g., 12 Volts) of a vehicle. Ignitionvoltage VIGN is applied to a resistor to generate a reference current,which is equal to the ignition voltage divided by the value of theresistor. This reference current establishes the current source and sinklevel for charging and discharging an external capacitor through whichthe variable oscillator 51 is connected to ground. Because the variableoscillator 51 is connected to the ignition voltage VIGN, the oscillator51 will provide a clock signal PCLK to one-shot circuitry 50 that isinversely proportional to the supply voltage VIGN level. Therefore, asVIGN increases, the one-shot and blanking time of the signal generatedby one-shot circuitry 50 in response to a trigger signal from sensingand detection circuitry 41 will decrease linearly.

FIG. 11 illustrates a detailed circuit implementation of an oscillator51 that provides a PCLK signal to one-shot circuitry 50, according toanother exemplary embodiment. I_(Ref) is shown being equal to VIGNdivided by R1. The bases of transistors Q2 and Q3 are in parallel withtransistor Q1. Thus, the current flowing in the collector of Q1 is alsothe collector current of transistors Q2 and Q3. The collector current oftransistor Q2 is the source of P-channel FET M1 gate to source shorted.The source current of M1 is equal to the source current of M2. Thisdisables the N-channel FET M4 and enables the P-channel FET M3. Thecurrent source M2 is enabled and the current sink Q3 is disabled. Theoutput voltage increases from 0 to 2 Volts DC. At this point, theoutputs of 58 and 59 go from a logic 0 to a logic 1. This causes theflip-flop 56 to toggle states resulting in PCLK. This enables theN-channel FET M4 and disables the P-channel FET M3. The current sourceM2 is disabled and the current sink Q3 is enabled. The oscillatorvoltage continues to decrease linearly to one Volt (1V) DC. Thisdisables the N-channel FET M4 and enables the P-channel FET M3. Thecurrent source M2 is enabled and the current sink Q3 is disabled. Thisramping up-down voltage sequence continues indefinitely until theintegrated circuit goes into a sleep mode. As noted above, the resultingoutput of the circuit generally illustrated in FIG. 11 is a PCLK signalthat varies linearly with the voltage input to variable oscillator 51.

Referring to FIG. 12, an electric motor control system is generallyillustrated, according to a third embodiment of the present invention.In this embodiment, the motor control system includes brake filtercircuitry 21, in addition to the other elements shown in the embodimentof FIG. 1. It should be appreciated that brake filter circuitry 21 couldgenerally be included in the other embodiments. The motor control systemaccording to this embodiment operates in a manner similar to theembodiment described in FIG. 1, with the added benefit that the motorshaft position detection system is improved by the addition of brakefilter circuitry 21, making the system insensitive to the inductivekickback generated by shorting the motor windings when it is commandedto brake. Brake filter circuitry 21 does this by synchronizing the brakecommand received from microcontroller 12 with a one-shot pulse issued byone-shot circuitry 50.

FIG. 13 provides an exemplary embodiment of the brake filter circuitry21 described in FIG. 12. When a brake command indicated by amicrocontroller (MIC) input of voltage VCC/2 is issued bymicrocontroller 12, it is passed on by voltage level decoder 22 toflip-flop 25. A brake signal Q is only issued from flip-flop 25 to gatedrive logic 20 after the falling edge of a subsequent one-shot pulsefrom one-shot circuitry 50 is received by flip-flop 25. The one-shotpulse issued by one-shot circuitry 50 is generated by a trigger fromsensing and detection circuitry 40 indicating that a valid event hasoccurred. The one-shot pulse issued by one-shot circuitry 50 is followedby a blanking period, also known as a dead-time, to act to mask outnoise from noise sources. As illustrated in FIGS. 12 and 13, the brakefilter circuitry 21 effectively synchronizes the brake command receivedfrom microcontroller 12, with the one-shot pulse issued by one-shotcircuitry 50. Using this system, energy from the inductive kickbackcreated due to shorting the motor windings during a brake command doesnot create a false pulse via sensing and detection circuitry 40 andone-shot circuitry 50. As a result, a source of error is eliminated.

FIG. 14 is a state diagram generally illustrating the operation of thebrake filter circuitry 21 employed in the motor control system of FIG.12. While the motor is operating in run mode, it receives run signalsfrom microcontroller 12. When microcontroller 12 issues a brake command,the brake filter circuitry 21 enters a wait state until a one-shot pulseis issued from one-shot circuitry 50. When the one-shot pulse fromone-shot circuitry 50 has been received by the brake filter circuitry,the brake command is then passed on to the gate drive logic 23 and on tomotors 30, causing them to brake and stop. Each of the motors begins torun again when run signals are received by the motor frommicrocontroller 12. It should be noted that brake filter circuitry 21could be located anywhere within the motor control circuitry provided itis able to receive one-shot pulses from one-shot circuitry 50 andcontrol and command signals from microcontroller 12, and provided it isable to issue signals to the gate drive logic controlling the motors 30.

Referring to FIG. 15, an electric motor control system is generallyillustrated, according to a fourth embodiment of the present invention.This embodiment of the motor control system operates in a manner similarto the embodiment described in FIG. 1. However, the motor controlsystem, according to the fourth embodiment, incorporates motor multiplexcircuitry 60 for allowing motor control circuitry 10 and microcontroller12 to control additional DC motors. Motor multiplex circuitry 60receives signals from pulse count driver circuitry 20 andmicrocontroller 12, and uses those signals to control which of aplurality of multiplexed motors will be driven. It should be appreciatedthat any number of multiplexed motors may be controlled by the motorcontrol system. Where communication occurs among any of motor multiplexcircuitry 60, pulse count driver circuitry 20, microcontroller 12,one-shot circuitry 50, sensing and detection circuitry 40, and motorcontrol circuitry 10, the means of communication may include, but is notlimited to, SPI, I2C and LIN.

FIG. 17 illustrates exemplary circuitry for implementing the motormultiplex circuitry in the motor control system, according to the fourthembodiment. In this implementation, the pulse count motor driver shownas QPC3 includes four full H-bridge driver circuits, four high-sidecurrent sensing circuits, and four detection circuits. QPC3 and amicroprocessor (corresponding to microcontroller 12 of FIG. 15) areshown connected to motor multiplex circuitry (corresponding to motormultiplex circuitry 60 of FIG. 15) that provides the capability tointerface to two additional external motors (Motors 5 and 6 in FIG. 17).In this implementation, channels 3 and 4 of QPC3 are multiplexed withexternal driver circuitry of fifth and sixth channels, respectively.This motor control system results in the capability of controlling atotal of six motors, with up to four motors able to operatesimultaneously. In this exemplary configuration, only motor 3 or 5and/or motor 4 or 6 can be operated at one time. However, other motorcombinations can be combined to control different numbers andcombinations of motors simultaneously.

The internal high-side driver output 3 illustrated in FIG. 17 isdisabled with a predefined bit pattern (0101) written via serialcommunications to data input DI control bits of QPC3. The motor controlinput 5 shown as MIC5 can now transition from a logic 1 to a logic 0.The MIC3 input controls whether low-side drivers M2 or M4 are enabled.In the embodiment shown, M1 and M3 remain disabled. After motor 5 hascompleted its commanded movement, the MIC5 input can now transition froma logic 0 to a logic 1. This mode is subsequently exited when asubsequent bit pattern, i.e., non-0101, is written to the control bitsof the DI register enabling normal H-bridge operation. Similarly, theinternal high-side driver output 4 is disabled when a 1010 is written tothe control bits of the DI SPI register bits 6 through 3. The MIC6output can now transition from a logic 1 to a logic 0. The MIC4 inputswill control whether low-side FETs M2 or M4 are enabled. Note that M1and M3 remain disabled. After motor 6 has completed its motor movement,the MIC6 input can now transition from a logic 0 to a logic 1. This modeis subsequently exited when a non-1010 pattern is written to the OSD3through zero bits of the DI SPI register enabling normal H-bridgeoperation.

Two additional microprocessor outputs and inputs are employed for eachinterface. One output MIC5/6 enables or disables an external MUX switch.The second input is used to disable both P-channel FETs M1 and M2 underfault conditions, e.g., short to ground or over-voltage. The two A-Dinputs monitor both sides of a motor for a short to ground condition.The state definitions for the various internal and external FETsillustrated in FIG. 17 and discussed above, are shown in FIG. 16.

The circuitry and method described above enables motor control circuitry20 to interface to and drive additional DC motors 30. For example, aquad pulse count driver circuit normally capable of driving only fourmotors is able, using the motor control system, according to the fourthembodiment, to drive six total channels, up to four of thosesimultaneously, according to one example.

Referring to FIGS. 18-19, a motor control system, according to a fifthembodiment of the present invention, is illustrated. The motor controlsystem, according to the fifth embodiment, is similar to that describedin FIG. 1, with the additional capability to switch between motorcontrol modes. In FIG. 18, each of brush-type DC motors 30 is generallyshown having a dedicated connection to a specific high-side driver ofpulse count driver circuitry 20 and low-side driver of pulse countdriver circuitry 20. Because each brush-type DC motor 30 has a dedicatedconnection to high- and low-side drivers associated with that specificmotor, each motor 30 can simultaneously and independently be driven bypulse count driver circuitry 20. This is known as simultaneous driveoperation.

FIG. 19 generally illustrates an electric motor control system similarto that illustrated in FIG. 18. However, in contrast to FIG. 18, whichgenerally shows each brush-type DC motor having dedicated connection tohigh- and low-side drivers, FIG. 19 generally shows only one low-sidedriver being connected to multiple brush-type DC motors at the sametime. In other words, although each brush-type DC motor 30 is generallyshown on high input H having a dedicated connection to a specifichigh-side driver of pulse count driver circuitry 20, the brush-type DCmotors 30 are generally shown on low input L sharing one low-side driverof pulse count driver circuitry 20. This configuration is known assequential drive operation. In the sequential mode, because all of theH-bridges in the pulse count driver circuitry 20 share a common bottomside, additional wires between multiple low-side drivers and multiplebrush-type DC motors 30 can be eliminated. However, in the sequentialmode, only one brush-type DC motor can be driven at a time. In thesequential mode, the operation of the individual H-bridges depend on thestate of the others because of the common bottom side driver connection.In contrast, in simultaneous mode, all H-bridges will respond to theirindividual control inputs and will work independent of the state of theother H-bridges. This allows each motor 30 to be operated independentlyof the other motors 30 and simultaneously. It should be understood thatmicrocontroller 12, motor control circuitry 10, and pulse count drivercircuitry 20 can generally be linked by the SPI connection and cancommunicate via that SPI connection.

The illustration of the embodiment shown in FIGS. 18 and 19 will now bedescribed. When power is first applied to microcontroller 12 and motorcontrol circuitry 10, microcontroller 12 writes values into registers 16of motor control circuitry 10. These values are indicative of whether ornot the microcontroller 12 wishes motor control circuitry 10 to controlmotors in sequential or simultaneous mode. Motor control circuitry 10configures itself to control motors in sequential or simultaneous mode,based on the values that it finds stored in the registers 16. Motorcontrol circuitry 10 will continue to control the motors in the selectedsimultaneous or sequential mode until power is removed from the circuit.When power is again restored to the circuit, microcontroller 12 willagain write values to registers 16 indicating whether motor controlcircuitry 10 should operate in simultaneous or sequential mode.Typically, values are written from microcontroller 12 to motor controlcircuitry 10 via an SPI interface.

FIGS. 20-21 further illustrate the implementation of a simultaneousdrive mode and sequential drive mode utilizing a microcontroller 12 anda driver circuit 20. In this embodiment, an SPI connection is shownprovided between the microcontroller and driver circuitry. As notedabove, pulse count driver circuitry 20 selects between the sequentialand simultaneous configurations based on the state of bits written to aregister by microcontroller 12 via an SPI bus to pulse count drivercircuitry 20. Pulse count driver circuitry 20 is configured such that,when register bits are set, the pulse count driver circuitry 20 willoperate in the sequential mode.

FIGS. 20-21 also illustrate a motor control system according to a sixthembodiment of the present invention. In this embodiment, pulse countdriver circuitry 20 can be configured to monitor a bit (CNOP) frommicrocontroller 12 indicating when microcontroller 12 is not operatingproperly. Pulse count driver circuitry 20 can be configured such that,when it detects a CNOP bit, it will drive all four motors simultaneouslyin a predetermined direction. When this occurs, each motor 30 isindependently driven in the predetermined direction until a stallcondition is detected or until a master timeout event occurs. Duringthis mode of operation, motor commutations are independently detectedfor each of the motors 30 for stall detection. FIG. 22 illustrates astate definition matrix for the FETs of drive circuitry in theembodiment shown in FIGS. 20 and 21 utilizing a quad pulse count driverintegrated circuit configured to simultaneously drive all four motors ina predetermined direction when an SPI bit indicates an error condition.The control system of this sixth embodiment provides a benefit ofallowing the pulse count driver circuitry 20 to simultaneously drive allconnected motors 30 in a predetermined direction, when control circuitry10 is not operating properly.

FIG. 23 generally illustrates a motor control system, according to asixth embodiment, in which multiple aspects of the previously discussedembodiments are used together. The combined elements include theimproved sensing and detection circuitry 40 and method for more reliabledetecting the rotor position of brush-type DC motors 30, an oscillator51 connected to the battery voltage (V_(BATTERY)) for linearly varyingduration of pulses issuing from the one-shot circuitry 50 in response tosignals received from sensing and detection circuitry 40, brake filtercircuitry 21 for synchronizing the issuance of braking signals withpulses issued from one-shot circuitry 50, thereby eliminating anothersource of error in the detected rotor positions, and rotor multiplexcircuitry 60 for enabling pulse count driver circuitry 20 to control anddrive additional DC motors 30. In addition, motor control circuitry 10and pulse count driver circuitry 20 are capable of receiving SPI anderror signals from microcontroller 12 and using those signals to selectbetween sequential and simultaneous drive modes and to drive theconnected motors 30 in a clockwise direction, when an error mode isdetected.

As noted above, the motor control systems, according to the variousdisclosed embodiments, contribute to improve systems for controllingbrush-type DC motors 30 by increasing the number of motors 30 that canbe controlled by a given control system, improving the quality of thesignals detected in the signal conditioning circuitry, allowing thecontrol system to easily switch between multiple control modes, andallowing the system to be responsive to system error conditions, amongother advantages. While the motor control systems of the presentinvention are particularly well suited for brush-type DC motors, itshould be appreciated that certain aspects of the present invention maybe implemented to control other types of motors.

The above description is considered that of the preferred embodimentsonly. Modifications of the invention will occur to those skilled in theart and to those who make or use the invention. Therefore, it isunderstood that the embodiments shown in the drawings and describedabove are merely for illustrative purposes and not intended to limit thescope of the invention, which is defined by the following claims, asinterpreted according to the principles of patent law, including thedoctrine of equivalents.

1. A method for controlling sensitivity of a motor position detectionsystem to changes in battery voltage, comprising the steps of: providingmotor position detection circuitry coupled to a motor and includingpulse-generating circuitry configured to generate pulses responsive toan oscillator input; providing oscillator circuitry coupled to thepulse-generating circuitry; applying a voltage to the oscillatorcircuitry, causing the oscillator to oscillate at a frequency that is afunction of the applied voltage; and causing at least one of frequencyand duration of the pulses generated by the pulse-generating circuitryto vary as a function of the voltage.
 2. The method as defined in claim1, wherein the at least one of the frequency and duration of the pulsesvaries linearly as a function of the applied voltage.
 3. The method asdefined in claim 1, wherein the step of applying a voltage comprisesapplying the voltage from a battery through a resistor.
 4. The method asdefined in claim 1, wherein the motor position detection circuitry usesa current associated with the motor to determine the motor position. 5.The method as defined in claim 1, wherein both the frequency andduration of the pulses generated by the pulse generating circuitry arecaused to vary as a function of the voltage.
 6. The method as defined inclaim 1, wherein the method is employed on a vehicle.
 7. The method asdefined in claim 6, wherein the method is employed in a heating,ventilating or air conditioning system on the vehicle.
 8. The method asdefined in claim 1, wherein the motor position detection system detectsthe position of at least one DC motor.
 9. The method as defined in claim8, wherein the at least one DC motor is a brush-type DC motor.
 10. Asystem for controlling sensitivity of motor position detection tochanges in battery voltage, comprising: motor position detectioncircuitry including pulse-generating circuitry configured to generatesignals in response to a signal received from oscillator circuitry;oscillator circuitry coupled to said pulse-generating circuitry; abattery coupled to said oscillator, wherein said battery has a voltagedetermining the frequency of the oscillator such that at least one ofthe frequency and duration of signals generated by the pulse-generatingcircuitry varies as a function of the voltage of said battery.
 11. Thesystem as defined in claim 10, wherein said at least one of thefrequency and duration of signals generated by the pulse-generatingcircuitry varies linearly as a function of the battery voltage.
 12. Thesystem as defined in claim 10, wherein the battery is coupled to theoscillator by a resistor.
 13. The system as defined in claim 10, whereinthe motor position detection circuitry uses a current associated withthe motor to determine motor position.
 14. The system as defined inclaim 10, wherein the system is employed on a vehicle.
 15. The system asdefined in claim 14, wherein the system is employed on a heating,ventilating or air conditioning system on the vehicle.
 16. The system asdefined in claim 10, wherein the motor position detection circuitrydetects the position of at least one DC motor.
 17. The system as definedin claim 16, wherein the at least one DC motor is a brush-type DC motor.